WO2018178163A1 - High voltage transformer and method for production thereof - Google Patents

Abstract

The invention relates to a high voltage transformer (1) comprising a primary circuit having a primary winding (101), a secondary circuit having at least two secondary windings (301a, 301b), which are connected in series and decoupled by at least one blocking diode (303a), and a core (500) on which the primary winding (101) and the at least two secondary windings (301a, 301b) are arranged at least in part, characterized in that the at least two secondary windings (301a, 301b) are arranged spaced apart from each other on the core, and that the at least one blocking diode (303a) is arranged within the core (500). The invention further relates to a method for producing the high voltage transformer (1) according to the invention.

Description

 High voltage transformer and method of making the same

The present invention relates to a high voltage transformer and a method of manufacturing this high voltage transformer.

High-voltage transformers are used to generate very high alternating voltages, with the voltage at the secondary coil, that is to say at the output, usually being a multiple of the input voltage at the primary coil. High-voltage transformers are used, for example, in switched-mode power supply technology.

High voltage transformers are known per se from the prior art. For example, DE 101 10 609 B4 describes a high-voltage power supply which comprises a generic high-voltage transformer. This high-voltage transformer has at least two windings connected in series in the high-voltage secondary circuit and a circuit breaker in the low-voltage primary circuit. The windings in the high-voltage secondary circuit are decoupled by at least one charging diode. The high-voltage power supply of DE 101 10 609 B4 is intended to achieve a distortion-free as possible voltage gain.

Furthermore, from DE 36 00 205 C2, for example, a high-voltage power supply for an X-ray tube is known, which also includes a high-voltage transformer for increasing the AC output voltage of an inverter. Due to the presence of a leakage inductance of this high-voltage transformer and the capacity of the high-voltage cable, the output voltage of the high-voltage rectifier circuit constructed from rectifier elements is smoothed in DE 36 00 205 C2. This should be minimized in the specific case, an unwanted ripple component in the X-ray tube DC voltage.

In the case of high voltage transformers, the prior art has problems with electromagnetic compatibility (EMC). That is, the high-voltage transformer can interfere with other technical devices by unwanted electrical or electromagnetic effects. By occurring in the case of the high-voltage transformer on the secondary side Magnetic fields is the legally prescribed electromagnetic compatibility is not always given.

In order to improve the electromagnetic compatibility, the individual series-connected windings of the high-voltage secondary circuit are decoupled from one another by diodes in the prior art (cf., for example, DE 101 10 609 B4). FIG. 1 of the present invention shows a functional diagram in which the individual windings W1 to W4 are contacted with the pins P1 to P1 1 on a printed circuit board (900), the four diodes D1 to D4 shown in this case likewise being mounted on the printed circuit board (FIG. 900). For this contacting or assembly on a printed circuit board, the diodes D1 to D4 are usually led over very long contact legs on the circuit board, which leads to increased problems with the electromagnetic compatibility. The prior art therefore provides for compliance with the electromagnetic compatibility, for example, according to DE 10 2013 109 538 A1 electrically conductive housing for shielding of electromagnetic interference signals around corresponding field devices arranged around.

Other proposed solutions are transformers with externally arranged diodes or transformers with diodes soldered directly to the windings. However, these complex technical solutions are only practical for special applications in which the high production costs are not significant. Unproblematic electromagnetic compatibility and the possibility of mass production do not exist here. In view of the foregoing prior art, it is an object of the present invention to provide a high voltage transformer which exhibits a very high electromagnetic compatibility and, moreover, is accessible to mass production by simplifying the structure. Furthermore, the aim is to provide a method for producing such a high-voltage transformer.

The above object is achieved in a first aspect of the present invention by a high voltage transformer (1) comprising

a primary circuit having a primary winding (101),

- A secondary circuit having at least two secondary windings (301 a, 301 b), which are connected in series and decoupled with at least one blocking diode (303 a), and a core (500) on which the primary winding (101) and the at least two

Secondary windings (301 a, 301 b) are at least partially arranged,

characterized,

that the at least two secondary windings (301 a, 301 b) have a spaced-apart arrangement on the core (500), and

in that the at least one blocking diode (303a) is arranged inside the core (500).

In a second aspect of the present invention, the object is achieved by a method for producing a high-voltage transformer (1), comprising the steps:

a) providing a primary winding (101) on a first carrier (103), b) attaching at least one blocking diode (303a) on the second carrier (305), b) applying at least two secondary windings (301 a, 301 b) on the second Carrier (305) and thereby contacting the at least one blocking diode (303 a), so that the at least two secondary windings (301 a, 301 b) are decoupled by means of the at least one blocking diode (303 a),

d) inserting the primary winding (101) on the first carrier (103) into a second carrier (305),

e) attaching a core (500), whereby at least a part of the core (500) at least partially surrounds the at least two secondary windings (301 a, 301 b) on its outer side, so that the at least one blocking diode (303 a) within the core (500 ) is arranged.

The present invention generally has the advantage that disturbances in the electromagnetic compatibility of a high-voltage transformer are significantly minimized. Furthermore, the present invention enables a production-suitable production of high-voltage transformers.

The invention will be described in detail below.

If method features are mentioned in the description of the high-voltage transformer (1) according to the invention, these relate in particular to the method according to the invention. Likewise, representational features that are cited in the description of the method according to the invention, on the high-voltage transformer (1) according to the invention. The first aspect of the present invention relates to a high voltage transformer (1) comprising a primary circuit having a primary winding (101) and a secondary circuit having at least two secondary windings (301 a, 301 b). The at least two secondary windings (301 a, 301 b) are connected in series and decoupled with at least one blocking diode (303 a) provided between them. The high-voltage transformer (1) further comprises a core (500) on which the primary winding (101) and the at least two secondary windings (301 a, 301 b) are at least partially arranged. The high-voltage transformer (1) according to the invention is characterized in that the at least two secondary windings (301 a, 301 b) have a spaced-apart arrangement on the core (500) and that the at least one blocking diode (303 a) within the core (500 ) is arranged. In the context of the present invention, "primary circuit with the primary winding (101)" is understood to mean the input side or primary side of the high-voltage transformer (1) at which a lower voltage is applied in comparison to the output side or secondary side V to 35 V, more preferably 12 V to 16 V.

The at least one blocking diode (303a) serves to decouple the at least two secondary windings (301a, 301b), that is, the series resonance frequency and the parallel resonance are shifted to higher frequency ranges. In a concrete example of the present invention, the series resonance frequency is 1.5 MHz and the parallel resonance frequency is 250 kHz.

The inventively provided spaced apart arrangement of the at least two secondary windings (301 a, 301 b) on the core (500) makes it possible to arrange the at least one blocking diode (303a) in series so that it is disposed within the core (500) means that the material of the core (500) forms an additional shield on the outside of the at least one blocking diode (303a).

The high-voltage transformer (1) according to the invention initially has the advantage that the interference caused by it electromagnetic compatibility (EMC) compared to generic high-voltage transformers clearly are minimized. In addition, the high-voltage transformer (1) according to the invention can be produced in a production suitable for production, which considerably reduces the unit price. In a further development of the high-voltage transformer (1) according to the invention, the spaced-apart arrangement of the at least two secondary windings (301 a, 301 b) has the same winding directions of all secondary windings (301 a, 301 b). This is advantageously achieved that the differential voltage between the secondary windings (301 a, 301 b) is the same at each point. In addition, the secondary windings (301 a, 301 b) can be wound better in the series.

A particular embodiment provides for four separate secondary windings (301 a, 301 b, 301 c, 301 d). Furthermore, it is advantageous if the high-voltage side of each secondary winding (301 a, 301 b) is held on the inside. As a result, an even better electromagnetic compatibility is achieved.

Another development of the high-voltage transformer (1) according to the invention is that the primary winding (101) within the at least two secondary windings (301 a, 301 b) is arranged. This development advantageously leads to a minimized size of the high-voltage transformer (1) according to the invention.

In a further embodiment of the high-voltage transformer (1) according to the invention, the primary winding (101) and the at least two secondary windings (301 a, 301 b) on separate carriers (103, 305) are applied, which are arranged one inside the other. Specifically, the first carrier (103) with the primary winding (101) applied thereto is arranged within the second carrier (305) with the at least two secondary windings (301 a, 301 b) applied thereto. In this case, the primary winding (101) is advantageously wound with eight parallel wires, so that the primary winding (101) and in this embodiment four separate secondary windings (301 a, 301 b, 301 c, 301 d), with the same winding width, symmetrically one above the other lie. It is also advantageous to achieve a smaller leakage inductance, the primary winding (101) so widen (for example, by parallel wires or Flat cable), that the primary winding (101) under each of the secondary windings (301 a, 301 b) comes to rest (see Figure 3).

In a preferred embodiment of the high-voltage transformer (1) according to the invention, the core (500) is a two-part core with two core halves (500a, 500b).

This embodiment of the core (500) as a two-part core with two core halves (500a, 500b) facilitates the mass production of the high-voltage transformer (1) by first the primary winding (101) and the at least two secondary windings (301 a, 301 b) provided can be before the two core halves (500a, 500b) are joined together.

A development of the high-voltage transformer (1) according to the invention provides that each core half (500a, 500b) has a jacket portion (501a, 501b) and a central portion (503a, 503b), wherein the central portion (503a, 503b) in the Inner of the primary winding (101) protrudes at least partially and the shell portion (501 a, 501 b) at least partially surrounds the at least two secondary windings (301 a, 301 b) on its outer side.

Compared to the prior art (toroidal cores or stacked sheet cores in the form of so-called El cores, M cores, UI cores and double L cores), in which the primary winding and the secondary windings are arranged on different parts of a core offers the inventive high-voltage transformer (1) has the advantage of a very compact design, in which the primary winding (101) and the at least two secondary windings (301 a, 301 b) use the same central portion (503a, 503b) of the core (500). The core (500) according to the invention may also be referred to as a "double E core" based on the prior art The jacket section (501a, 501b) provided according to the invention serves for the at least one blocking diode (303a) on the outside of the high voltage transformer (1) so as to ensure the additional shielding of the blocking diode (303a) according to the invention.

In order to improve the production suitable for production even further, in another embodiment of the high-voltage transformer (1) according to the invention at least one blocking diode (303a) mounted on an internal mounting board (700) disposed within the core (500). In an advantageous manner, the mounting plate (700) with at least one blocking diode (303a) mounted thereon is first mounted on the second carrier (305) before the at least two secondary windings (301a, 301b) are then applied to the first carrier (103) become.

In one embodiment of the high-voltage transformer (1) according to the invention, this can be modulated with an output voltage of 0 V to 6,000 V. The modulability of the high-voltage transformer (1) according to the invention is achieved by a pulsed input voltage (primary voltage) with a frequency between 60 kHz and 300 kHz.

The preferred output voltage is thus between 0 V and 6,000 V, the preferred input voltage is between 9 V and 35 V, preferably between 12 V and 16 V.

Advantageously, the high-voltage transformer (1) according to the invention achieves an output power of at least 5 W, preferably between 50 W and 100 W.

The above statements and preferences with regard to the high-voltage transformer (1) according to the invention apply correspondingly to the inventive method described below. Likewise, the following statements and preferences with regard to the inventive method for the high-voltage transformer (1) according to the invention apply accordingly.

The second aspect of the present invention relates to a method for manufacturing the high-voltage transformer (1) according to the invention. The method according to the invention initially comprises a step a) in which a primary winding (101) is provided on a first carrier (103) before at least one blocking diode (303a) is mounted on a second carrier (305) in a step b).

The first carrier (103) and / or the second carrier (305) are / is to be made of a suitable material. In a step c) at least two secondary windings (301 a, 301 b) are applied to the second carrier (305) and thereby contacted the at least one blocking diode (303 a), so that the at least two secondary windings (301 a, 301 b) by means of at least one blocking diode (303a) are decoupled.

In a step d), the primary winding (101) provided in step a) is introduced on the first carrier (103) into the second carrier (305), so that the primary winding (101) and the at least two secondary windings (301 a, 301 b ) are arranged substantially concentrically. In this case, the primary winding (101) is preferably positioned so that each individual winding comes to rest under one of the at least two secondary windings (301 a, 301 b).

Finally, in a step e), a core (500) is attached, whereby at least part of the core (500) at least partially surrounds the at least two secondary windings (301 a, 301 b) on its outer side, so that the at least one blocking diode (303 a) is disposed within the core (500).

The phrase "disposed within the core (500)" in the sense of the present invention means that the at least one blocking diode (303a) is positioned in the high-voltage transformer (1) according to the invention so as to be shielded by the material of the core (500) becomes.

The inventive method basically has the same advantages as the high-voltage transformer (1) according to the invention according to the first aspect of the invention. In particular, by the method according to the invention, the high-voltage transformer (1) according to the invention can be produced in a production suitable for production, which considerably reduces the unit price. In a development of the method according to the invention, the at least one blocking diode (303a) is attached in step b) by means of a pre-equipped internal component board (700), which is mounted on the second carrier (305) after being equipped with the at least one blocking diode (303a) before the at least two secondary windings (301 a, 301 b) are applied. By this measure, the production suitable for production is further improved, since in a conventional automated process, first the mounting board (700) can be created before - preferably automatically - on the second carrier (305) is mounted.

Other objects, features, advantages and applications will become apparent from the following description of the invention not limiting embodiments with reference to FIGS. All described and / or illustrated features alone or in any combination form the subject matter of the invention, regardless of their combination in the claims or their dependency. Show it:

1 is a schematic functional diagram of a high-voltage transformer according to the prior art,

Fig. 2 is a schematic functional diagram of the high-voltage transformer 1 according to the invention according to an embodiment of the invention and

 3 shows a schematic section through the high-voltage transformer 1 according to the invention.

Figure 1 shows, as already stated above, the schematic diagram of a high-voltage transformer according to the prior art. The pins P1 to P1 1 are contacted as the individual windings W1 to W4 on a circuit board 900. The four diodes D1 to D4 are also equipped on this printed circuit board 900, which according to the prior art, these diodes D1 to D4 must be partially soldered by hand.

FIG. 2 shows a functional diagram, similar to the representation of FIG. 1, of the high-voltage transformer 1 according to the present invention. Here, the placement of the at least two secondary windings 301a, 301b and the at least one blocking diode 303a is now changed so that the pins P4 to P10 can be listed as so-called "internal pins." The term "internal pins" means according to the present invention Invention that from the system "potted high-voltage transformer 1" these pins are not led out and can be achieved after potting. The pins P1 and P2 represent the connection pins of the primary coil, while the pins P3 and P1 1 represent the connection pins of the at least two secondary windings 301 a, 301 b. These connection pins P1, P2, P3 and P1 1 are contacted on the circuit board 900.

As a result of this changed placement of windings and diodes, the blocking diodes 303a, 303b, 303c, 303d can be placed within the high-voltage transformer 1 according to the invention, which was not possible with conventional transformer windings according to the prior art.

FIG. 3 shows schematically the section through the high-voltage transformer 1 according to the invention, from which it can be seen how the blocking diodes 303 a, 303 b, 303 c, 303 d are arranged inside the high-voltage transformer 1, that is to say inside the core 500. For better clarity, the same parts are provided only once with reference numerals.

On the first carrier 103, the primary winding 101 is applied. On the second carrier 305, the at least two secondary windings 301 a, 301 b are applied, wherein in the representation of Figure 3 preferably four secondary windings 301 a, 301 b, 301 c, 301 d are shown. On the second carrier 305, the at least one blocking diode 303a, in the illustrated preferred embodiment, four blocking diodes 303a, 303b, 303c, 303d, first applied before the secondary windings 301 a, 301 b, 301 c, 301 d are applied. This has the advantage that in a special embodiment, the blocking diodes 303a, 303b, 303c, 303d can be equipped on the internal assembly board 700 by machine. By using this internal mounting board 700, it is possible not only the blocking diodes 303a, 303b, 303c, 303d, but also the pins P3 and P1 1 for contacting the secondary windings 301 a, 301 b, 301 c, 301 d cost in series with equip. After completion of the primary circuit and the secondary circuit, the two core halves 500a, 500b of the core 500 can be joined together, the two central sections 503a, 503b are arranged inside the primary and secondary circuits, while the shell sections 501 a, 501 b on the outside arranged secondary circuit surrounded by the outside. As can be seen from the illustration of FIG. 3, the arrangement of the blocking diodes 303a, 303b, 303c, 303d thereby becomes the interior of the high-voltage transformer 1, that is, the interior of the core 500 recorded, whereby a very good electromagnetic compatibility is achieved.

Finally, the high-voltage transformer 1 according to the invention is contacted on the guide plate 900.

The high voltage transformer 1 of the present invention replaces prior art generic transformers with external diodes or experimental Applicant transformers with internally hand soldered diodes. As a result, a previously unknown electromagnetic compatibility is achieved and combined with a very good mass production option.

In addition, a technical solution for a modulatable high-voltage transformer 1 is created, on the one hand enables the requirements for electromagnetic compatibility and on the other hand, a very compact space.

reference numeral

1 high voltage transformer

101 primary winding

 103 first carrier

 301a, 301b secondary windings

 301c, 301d secondary windings

 303a, 303b blocking diodes

 303c, 303d blocking diodes

 305 second carrier

 500 core

 500a, 500b core halves

 501a, 501b shell sections

 503a, 503b Central sections

 700 internal assembly board

900 circuit board

 D1 - D4 diodes

 P1 -P11 pins

 W1 -W4 secondary windings

Claims

claims 1 . High voltage transformer (1) comprising  a primary circuit having a primary winding (101),  - A secondary circuit having at least two secondary windings (301 a, 301 b), which are connected in series and decoupled with at least one blocking diode (303 a), and - a core (500) on which the primary winding (101) and the at least two secondary windings (301 a, 301 b) are at least partially arranged, characterized  that the at least two secondary windings (301 a, 301 b) have a spaced-apart arrangement on the core (500), and  in that the at least one blocking diode (303a) is arranged inside the core (500). 2. High-voltage transformer (1) according to claim 1, wherein the spaced-apart arrangement of the at least two secondary windings (301 a, 301 b) have the same winding directions of all secondary windings (301 a, 301 b). 3. High-voltage transformer (1) according to claim 1 or 2, wherein the primary winding (101) within the at least two secondary windings (301 a, 301 b) is arranged. 4. High-voltage transformer (1) according to claim 3, wherein the primary winding (101) and the at least two secondary windings (301 a, 301 b) on separate Carriers (103, 305) are applied, which are arranged inside each other. The high voltage transformer (1) according to any one of claims 1 to 4, wherein the core (500) is a two-piece core having two core halves (500a, 500b), each core half (500a, 500b) comprising a skirt portion (501 a, 501 b) and one Central portion (503a, 503b), wherein the central portion (503a, 503b) projects into the interior of the primary winding (101) at least partially and the shell portion (501 a, 501 b), the at least two secondary windings (301 a, 301 b) on their Outside at least partially encloses. A high voltage transformer (1) according to any one of claims 1 to 5, wherein the at least one blocking diode (303a) is mounted on an internal mounting board (700) disposed within the core (500). High-voltage transformer (1) according to one of claims 1 to 6, wherein the high-voltage transformer (1) with an output voltage of 0 V to 6,000 V is modulated. A high voltage transformer (1) according to any one of claims 1 to 7, wherein the high voltage transformer (1) reaches an output power of at least 5W. Method for producing a high-voltage transformer (1) according to one of Claims 1 to 8, comprising the steps: a) providing a primary winding (101) on a first carrier (103), b) attaching at least one blocking diode (303a) on a second carrier (305), c) applying at least two secondary windings (301 a, 301 b) on the second Carrier (305) and thereby contacting the at least one blocking diode (303 a), so that the at least two secondary windings (301 a, 301 b) are decoupled by means of the at least one blocking diode (303 a), d) inserting the primary winding (101) on the first carrier (103) into the second carrier (305), e) attaching a core (500), whereby at least a part of the core (500) at least partially surrounds the at least two secondary windings (301 a, 301 b) on its outer side, so that the at least one blocking diode (303 a) within the core (500 ) is arranged. The method of claim 9, wherein attaching the at least one blocking diode (303a) in step b) is by means of a pre-assembled internal mounting board (700) mounted on the second carrier (305) before the at least two secondary windings (301 a, 301 b) are applied.